A genetic analysis of synaptic development: pre- and postsynaptic dCBP control transmitter release at the Drosophila NMJ

Postsynaptic dCBP (Drosophila homolog of the CREB binding protein) is required for presynaptic functional development. Viable, hypomorphic dCBP mutations have a approximately 50% reduction in presynaptic transmitter release without altering the Ca2+ cooperativity of release or synaptic ultrastructure (total bouton number is increased by 25%-30%). Exogenous expression of dCBP in muscle rescues impaired presynaptic release in the dCBP mutant background, while presynaptic dCBP expression does not. In addition, overexpression experiments indicate that elevated dCBP can also inhibit presynaptic functional development in a manner distinct from the effects of dCBP loss of function. Pre- or postsynaptic overexpression of dCBP (in wild type) reduces presynaptic release. However, we do not observe an increase in bouton number, and presynaptic overexpression impairs short-term facilitation. These data suggest that dCBP participates in a postsynaptic regulatory system that controls functional synaptic development.     

Identification of Escherichia coli ubiB, a gene required for the first monooxygenase step in ubiquinone biosynthesis

It was recently discovered that the aarF gene in Providencia stuartii is required for coenzyme Q (CoQ) biosynthesis. Here we report that yigR, the Escherichia coli homologue of aarF, is ubiB, a gene required for the first monooxygenase step in CoQ biosynthesis. Both the P. stuartii aarF and E. coli ubiB (yigR) disruption mutant strains lack CoQ and accumulate octaprenylphenol. Octaprenylphenol is the CoQ biosynthetic intermediate found to accumulate in the E. coli strain AN59, which contains the ubiB409 mutant allele. Analysis of the mutation in the E. coli strain AN59 reveals no mutations within the ubiB gene, but instead shows the presence of an IS1 element at position +516 of the ubiE gene. The ubiE gene encodes a C-methyltransferase required for the synthesis of both CoQ and menaquinone, and it is the 5' gene in an operon containing ubiE, yigP, and ubiB. The data indicate that octaprenylphenol accumulates in AN59 as a result of a polar effect of the ubiE::IS1 mutation on the downstream ubiB gene. AN59 is complemented by a DNA segment containing the contiguous ubiE, yigP, and ubiB genes. Although transformation of AN59 with a DNA segment containing the ubiB coding region fails to restore CoQ biosynthesis, transformation with the ubiE coding region results in a low-frequency but significant rescue attributed to homologous recombination. In addition, the fre gene, previously considered to correspond to ubiB, was found not to be involved in CoQ biosynthesis. The ubiB gene is a member of a predicted protein kinase family of which the Saccharomyces cerevisiae ABC1 gene is the prototypic member. The possible protein kinase function of UbiB and Abc1 and the role these polypeptides may play in CoQ biosynthesis are discussed.     

The c-Jun NH(2)-terminal kinase promotes insulin resistance during association with insulin receptor substrate-1 and phosphorylation of Ser(307)

Tumor necrosis factor alpha (TNFalpha) inhibits insulin action, in part, through serine phosphorylation of IRS proteins; however, the phosphorylation sites that mediate the inhibition are unknown. TNFalpha promotes multipotential signal transduction cascades, including the activation of the Jun NH(2)-terminal kinase (JNK). Endogenous JNK associates with IRS-1 in Chinese hamster ovary cells. Anisomycin, a strong activator of JNK in these cells, stimulates the activity of JNK bound to IRS-1 and inhibits the insulin-stimulated tyrosine phosphorylation of IRS-1. Serine 307 is a major site of JNK phosphorylation in IRS-1. Mutation of serine 307 to alanine eliminates phosphorylation of IRS-1 by JNK and abrogates the inhibitory effect of TNFalpha on insulin-stimulated tyrosine phosphorylation of IRS-1. These results suggest that phosphorylation of serine 307 might mediate, at least partially, the inhibitory effect of proinflammatory cytokines like TNFalpha on IRS-1 function.     

Signaling lymphocytic activation molecule (CDw150) is homophilic but self-associates with very low affinity

Signaling lymphocytic activating molecule ((SLAM) CDw150) is a glycoprotein that belongs to the CD2 subset of the immunoglobulin superfamily and is expressed on the surface of activated T- and B-cells. It has been proposed that SLAM is homophilic and required for bidirectional signaling during T- and B-cell activation. Previous work has suggested that the affinity of SLAM self-association might be unusually high, undermining the concept that protein interactions mediating transient cell-cell contacts, such as those involving leukocytes, have to be weak in order that such contacts are readily reversible. Using surface plasmon resonance-based methods and analytical ultracentrifugation (AUC), we confirm that SLAM is homophilic. However, we also establish a new theoretical treatment of surface plasmon resonance-derived homophilic binding data, which indicates that SLAM-SLAM interactions (solution K(d) approximately 200 micrometer) are in fact considerably weaker than most other well characterized protein-protein interactions at the cell surface (solution K(d) approximately 0.4-20 micrometer), a conclusion that is supported by the AUC analysis. Whereas further analysis of the AUC data imply that SLAM could form "head to head" dimers spanning adjacent cells, the very low affinity raises important questions regarding the physiological role and/or properties of such interactions.     

Purification, cloning, and characterization of an acidic ectoprotein phosphatase differentially expressed in the infectious bloodstream form of Trypanosoma brucei

We purified an ecto-phosphatase of 115 kDa (TryAcP115) specifically expressed by bloodstream forms of Trypanosoma brucei. The corresponding gene coded for a 45-kDa protein potentially including a signal peptide, a membrane-spanning domain and an N-terminal domain containing 8 N-glycosylation sites. There was no significant sequence homology with other phosphatases. Antiserum to the Escherichia coli recombinant N-terminal domain, Petase7, recognized a protein of 55 kDa in Western blots after deglycosylation of the TryAcP115 protein by N-glycosidase F. Immunofluorescence and trypsin treatment of living parasites showed that TryAcP115 was localized to the surface of the parasite and that its N-terminal domain was oriented extracellularly. The recombinant N-terminal domains, expressed in E. coli and Leishmania amazonensis, harbored phosphatase activity against Tyr(P)-Raytide, Ser(P)-neurogranin, and ATP. The enzymatic properties of native TryAcP115 and the recombinant proteins for the substrate Tyr(P)-Raytide were virtually identical and included: (i) K(m) and V(max) values of 15 nM and 200 pmol/min/mg, (ii) no requirement for divalent cations, and (iii) sensitivity to vanadate, sodium fluoride, and tartrate, but insensitivity to okadaic acid and tetramisole. Although the function of TryAcP115 remains unknown, a differentially expressed, unique ecto-phosphatase could regulate growth or influence parasite-host interactions and might provide a useful target for chemotherapy.     

Recent advances in liver-directed gene therapy: implications for the treatment of dyslipidemia

Somatic gene therapy for the treatment of dyslipidemia is an area of active investigation. A substantial body of data indicates that the transfer of various lipid-lowering genes to the liver is an effective method of restoring normal plasma lipids in animal models of dyslipidemia. Most studies have used adenoviral vectors because of their excellent gene-transfer efficiency. However, the first and second-generation adenoviral vectors used in these experiments are highly toxic and are associated with substantial morbidity and mortality. This article reviews current data on the properties of two novel vectors, the adeno-associated virus and the helper-dependent adenovirus that is devoid of all protein-encoding genes. Each type of vector has its advantages and drawbacks. They appear to be the most promising vectors to date for liver-directed gene transfer in the treatment of dyslipidemia.     

Study of the complex formation of daunomycin with deoxytetranucleotides with bases of differing sequence in an aqueous solution by 1H-NMR spectroscopy

The complex formation of the antibiotic daunomycin with deoxytetranucleotides of different base sequence in the chain, 5'-d(GpCpGpC), 5'-d(CpGpCpG), and 5'-d(TpGpCpA) in aqueous salt solution was studied by 1D and 2D (2M-TOCSY and 2M-NOESY) 1H-NMR spectroscopy. Concentration and temperature dependences of proton chemical shifts of molecules were measured. Based on these dependences, reaction equilibrium constants, relative content of various complexes depending on concentration and temperature, limiting values of chemical shifts of protons of daunomycin incorporated in various complexes, and the thermodynamic parameters delta H and delta S of complex formation were calculated. The analysis of the results enables the conclusion that the sites of predominant intercalation of daunomycin are triplet nucleotide sequences, the binding sites of the antibiotic with three consecutive GC pairs in the tetranucleotide duplex being more preferential. Daunomycin exhibits no sequence specificity upon binding to the single-stranded deoxynucleotide sequence. From the calculated values of induced chemical shifts of daunomycin protons and 2M-NOE data, the most probable spatial structures of complexes (1:2) of the antibiotic with deoxytetranucleotides were constructed. The binding of the second daunomycin molecule to both the single-stranded and duplex form of tetramers is of pronounced anticooperative mode, which is explained by the presence in the antibiotic of a positively charged amino sugar residue, which poses considerable steric constraints for the insertion of the second antibiotic molecule into the short tetranucleotide sequence. The results were compared with the data obtained under identical experimental conditions for typical intercalators proflavine and ethidium bromide.     

Identification of a novel protein complex containing annexin VI, Fyn, Pyk2, and the p120(GAP) C2 domain

p120(GAP) (RasGAP) has been proposed to function as both an inhibitor and effector of Ras. Previously we have shown that RasGAP contains a C2 domain which mediates both Ca(2+)-dependent membrane association and protein-protein interactions. Specifically, three proteins have been isolated in a complex with the C2 domain of RasGAP; these are the Ca(2+)-dependent lipid binding protein annexin VI (p70) and two previously unidentified proteins, p55 and p120. Here we provide evidence that p55 is the Src family kinase Fyn and p120 is the focal adhesion kinase family member Pyk2. In addition, in vitro binding assays indicate that Fyn, but not Pyk2 binds directly to annexin VI. Finally, co-immunoprecipitation studies in Rat-1 fibroblasts confirm that Fyn, Pyk2, annexin VI and RasGAP can form a protein complex in mammalian cells.